|Bi-directional fast charger at Ft. Carson. Click to enlarge.|
A team of Burns & McDonnell engineers, along with subcontractor Coritech Services, has a system of bidirectional, fast-charging stations for a fleet of plug-in electric vehicles at Fort Carson, Colo. This first-of-its-kind system will push power back to the base microgrid when needed to meet installation demand or improve overall power quality.
On 29 August, the team successfully commissioned five bidirectional chargers and the aggregating control system as part of the Smart Power Infrastructure Demonstration for Energy Reliability and Security (SPIDERS) microgrid project at Fort Carson. (Earlier post.) Commissioning was performed using both Boulder Electric Vehicle and Smith Electric trucks, which are being provided for use on SPIDERS under separate agreements with the US Army’s Construction Engineering Research Laboratory (CERL) and Tank Automotive Research, Development and Engineering Center (TARDEC).
Commissioning of the vehicle charging stations represents an important milestone of the Fort Carson SPIDERS project, which is nearing completion. The project is managed by the US Army Corps of Engineers (USACE), Omaha District, and includes technical guidance from CERL and TARDEC.
The bidirectional charging units are capable of providing up to 300 kW of power to plug-in electric vehicles and also can discharge a like amount of stored energy from the vehicle batteries to the grid or microgrid via Society of Automotive Engineers (SAE) standard J1772-compliant bidirectional charging cables.
The vehicle-to-grid (V2G) charging includes power factor correction, which is a growing concern at locations such as Fort Carson that are experiencing a growth in on-site solar power generation, resulting in utility rate penalties.
Each of the five chargers have been tested to charge and discharge at full capacity of 60 kW, and have imported and exported a combined 394 kVAR (kilovolt-amperes reactive—reactive power that diminishes the real power capacity of transmission lines) to the local grid even when electric vehicles are not connected to the chargers. This provides a 24-hour-per-day benefit to Fort Carson by absorbing VARs from the grid, thus increasing the power factor of the loads at Fort Carson and making the transmission of power from the local utility more efficient and less costly.
The chargers are also integrated into the SPIDERS backup power microgrid, which allows the installation to utilize a fleet of bidirectional-capable electric vehicles as energy storage devices that, in conjunction with diesel generators and a 2-megawatt (MW) solar photovoltaic array, increases the reliability and efficiency of backup power systems to critical facilities at Fort Carson.
The Burns & McDonnell team also includes Southwest Research Institute (SwRI) and Intelligent Power & Energy Research Corporation (IPERC) that provided design, programming and aggregation of the vehicle charging solution and microgrid integration.
SPIDERS. The Smart Power Infrastructure Demonstration for Energy Reliability and Security () is three‐phase technology demonstration supported by the US Departments of Defense, Energy and Homeland Security.
Under the SPIDERS program, the DOD is and testing the effectiveness of utilizing multiple diesel generators in conjunction with photovoltaic (PV) arrays and other energy storage media to operate a stable, medium-voltage microgrid upon prolonged loss of utility power. The goals of the program are to increase reliability of backup power systems as well as reduce fuel consumption through more efficient use of backup power systems. One key feature of this program is that it utilizes existing assets whenever possible. Thus, it is not a “clean sheet” approach to creating microgrids but one that, instead, mimics what the DOD and private industry could do as a lowest cost approach.
Focused on three distinct military installations—Joint Base Pearl Harbor/Hickam, Hawaii; Fort Carson, Colorado; and Camp H.M. Smith, Hawaii—SPIDERS is to enable those facilities to operate independent from the bulk power grid (i.e., “islanded mode”) for extended time periods, with maximum assurance that cybersecurity is uncompromised.